Sage Journals: Discover world-class research

Abstract

A theoretical and experimental study is presented for the end- point control of a slender flexible arm driven by piezoelectric bimorph cells. A discrete-time formulation is presented for the arm-cell system and applied to the problem of moving the arm so that the tip closely tracks the fluctuation of target. The tip displacement (versus time) is compared with the target fluctuation, and the tip position error is used, together with other estimated system states, as the basis for applying control voltage to the cells. Both simulation and experimental results show that the PID control using the piezoelectric cells as the actuators is sufficient to make the arm tip follow the fluctuation of target precisely.

Get full access to this article

View all access options for this article.

References

Bailey, T. , and Hubbard, J.E. 1985. Distributed piezoelectric-polymer active vibration control of a cantilever beam. J. Guidance Control 8(5):605-611.

Baz, A. , and Poh, S. 1988. Performance of an active control system with piezoelectric actuators. J. Sound Vibration 126(2):327-343.

Book, W.J. , Maizza-Neto, O. , and Whitney, D.E. 1975. Feedback control of two beam, two joint systems with distributed flexibility. Trans. ASME J. Dyn. Sys. Meas. Control 97(4):424-431.

Cannon, R.H., Jr. , and Schmitz, E. 1984. Initial experiments on the end-point control of a flexible one-link robot. Int. J. Robot. Res. 3(3):62-75.

Chonan, S. , and Umeno, H. 1989. Closed-loop end-point control of a two-link flexible arm with a tip mass. J. Sound Vibration 133(3):483-495.

Fukuda, T. , and Arakawa, A. 1987. Control of flexible robotic arms. 2nd report, Modelling and basic control characteristic of second degree-of-freedom coupling system . In Japanese. Trans. JSME 53(C):201-208.

Lee, J.K. , and Marcus, M.A. 1981. The deflection-bandwidth product of PVF benders and related structures. Ferroelectronics 32:93-101.

Lee, J.D. , and Wang, B.L. 1988. Dynamic Equations for a two-link flexible robot arm. Computers Structures 29(3):469-477.

Ower, J.C. , and Van De Vegte, J. 1987. Classical control design for a flexible manipulator: Modeling and control system design. IEEE J. Robot. Automat. RA-3(5):485-489.

10.

Skaar, S.B. , and Tucker, D. 1986. Point control of a one-link flexible manipulator. Trans ASME J. Appl. Mechanics 53(1)23-27.

11.

Tahara, M. , and Chonan, S. 1988. Closed-loop displacement control of a one-link flexible arm with a tip mass. JSME Int. J. Series C 31(2):409-415.

12.

Tani, J. , Takahashi, F. , and Ueda, H. 1988. Active control of a vibration beam. Proceedings of the Sixteenth International Symposium on Space Technology and Science. pp. 571-576.

13.

Toda, M. , Osaka, S. , and Tosima, S. 1980. Large area display element using PVF2 bimorph with double support structure. Ferroelectronics 23:115-120.

14.

Toda, M. 1980. Elastic properties of piezoelectric PVF2. J. Appl. Physics 51(9):4673-4677.

15.

Uchino, K. 1986. Piezoelectric/piezostrain actuators. In Japanese. Tokyo, Japan: Morikita Press.

16.

Yigit, A. , Scott, R.A. , and Ulsoy, A.G. 1988. Flexible motion of a radially rotation beam attached to a rigid body. J. Sound Vibration 121:201-210.

17.

Yuh, J. 1987. Application of a discrete-time model reference adaptive control to a flexible single-link robot. J. Robot. Sys. 4(5):621-630.

Tracking Control of a Miniature Flexible Arm Using Piezoelectric Bimorph Cells

Abstract

Get full access to this article

References